Characterization of liver GSD IX γ2 pathophysiology in a novel Phkg2-/- mouse model.

INTRODUCTION: Liver Glycogen Storage Disease IX is a rare metabolic disorder of glycogen metabolism caused by deficiency of the phosphorylase kinase enzyme (PhK). Variants in the PHKG2 gene, encoding the liver-specific catalytic γ2 subunit of PhK, are associated with a liver GSD IX subtype known as PHKG2 GSD IX or GSD IX γ2. There is emerging evidence that patients with GSD IX γ2 can develop severe and progressive liver disease, yet research regarding the disease has been minimal to date. Here we characterize the first mouse model of liver GSD IX γ2. METHODS: A Phkg2-/- mouse model was generated via targeted removal of the Phkg2 gene. Knockout (Phkg2-/-, KO) and wild type (Phkg2+/+, WT) mice up to 3 months of age were compared for morphology, Phkg2 transcription, PhK enzyme activity, glycogen content, histology, serum liver markers, and urinary glucose tetrasaccharide Glcα1-6Glcα1-4Glcα1-4Glc (Glc4). RESULTS: When compared to WT controls, KO mice demonstrated significantly decreased liver PhK enzyme activity, increased liver: body weight ratio, and increased glycogen in the liver, with no glycogen accumulation observed in the brain, quadricep, kidney, and heart. KO mice demonstrated elevated liver blood markers as well as elevated urine Glc4, a commonly used biomarker for glycogen storage disease. KO mice demonstrated features of liver structural damage. Hematoxylin & Eosin and Masson's Trichrome stained KO mice liver histology slides revealed characteristic GSD hepatocyte architectural changes and early liver fibrosis, as have been reported in liver GSD patients. DISCUSSION: This study provides the first evidence of a mouse model that recapitulates the liver-specific pathology of patients with GSD IX γ2. The model will provide the first platform for further study of disease progression in GSD IX γ2 as well as for the evaluation of novel therapeutics.

GBE1-related disorders: Adult polyglucosan body disease and its neuromuscular phenotypes.

Adult polyglucosan body disease (APBD) represents a complex autosomal recessive inherited neurometabolic disorder due to homozygous or compound heterozygous pathogenic variants in GBE1 gene, resulting in deficiency of glycogen-branching enzyme and secondary storage of glycogen in the form of polyglucosan bodies, involving the skeletal muscle, diaphragm, peripheral nerve (including autonomic fibers), brain white matter, spinal cord, nerve roots, cerebellum, brainstem and to a lesser extent heart, lung, kidney, and liver cells. The diversity of new clinical presentations regarding neuromuscular involvement is astonishing and transformed APBD in a key differential diagnosis of completely different clinical conditions, including axonal and demyelinating sensorimotor polyneuropathy, progressive spastic paraparesis, motor neuronopathy presentations, autonomic disturbances, leukodystrophies or even pure myopathic involvement with limb-girdle pattern of weakness. This review article aims to summarize the main clinical, biochemical, genetic, and diagnostic aspects regarding APBD with special focus on neuromuscular presentations.

GYS1 or PPP1R3C deficiency rescues murine adult polyglucosan body disease.

OBJECTIVE: Adult polyglucosan body disease (APBD) is an adult-onset neurological variant of glycogen storage disease type IV. APBD is caused by recessive mutations in the glycogen branching enzyme gene, and the consequent accumulation of poorly branched glycogen aggregates called polyglucosan bodies in the nervous system. There are presently no treatments for APBD. Here, we test whether downregulation of glycogen synthesis is therapeutic in a mouse model of the disease. METHODS: We characterized the effects of knocking out two pro-glycogenic proteins in an APBD mouse model. APBD mice were crossed with mice deficient in glycogen synthase (GYS1), or mice deficient in protein phosphatase 1 regulatory subunit 3C (PPP1R3C), a protein involved in the activation of GYS1. Phenotypic and histological parameters were analyzed and glycogen was quantified. RESULTS: APBD mice deficient in GYS1 or PPP1R3C demonstrated improvements in life span, morphology, and behavioral assays of neuromuscular function. Histological analysis revealed a reduction in polyglucosan body accumulation and of astro- and micro-gliosis in the brains of GYS1- and PPP1R3C-deficient APBD mice. Brain glycogen quantification confirmed the reduction in abnormal glycogen accumulation. Analysis of skeletal muscle, heart, and liver found that GYS1 deficiency reduced polyglucosan body accumulation in all three tissues and PPP1R3C knockout reduced skeletal muscle polyglucosan bodies. INTERPRETATION: GYS1 and PPP1R3C are effective therapeutic targets in the APBD mouse model. These findings represent a critical step toward the development of a treatment for APBD and potentially other glycogen storage disease type IV patients.

[Hepatic glycogenosis: a case report]. / Glucogenosis hepá tica: a propósito de un caso.

The glycogen storage diseases contain a range of diseases that are characterized by the abnormal storage or utilization of glycogen, the organs most affected being muscle and / or liver. Hepatomegaly may be a clinical sign that could guide to the diagnosis. We describe a 15-year-old patient with hepatomegaly, hypertransaminasemia and growth retardation. He was diagnosed with a glycogen storage disease by liver biopsy.

No effect of oral sucrose or IV glucose during exercise in phosphorylase b kinase deficiency.

This case report investigated exercise metabolism and the effect of oral sucrose and intravenous glucose supplementation in a 30-year-old, mildly affected man with muscle phosphorylase b kinase (PHK) deficiency caused by a novel c.586G>A mutation in the PHKA1 gene. Only 12 patients with PHK deficiency have been reported and it is unclear to what extent patients exhibit symptoms during exercise. Carbohydrate and fat metabolism were measured during 30 min of exercise at ∼ 70% of peak oxidative capacity using stabile isotope technique and signaling proteins and enzymes in the energy pathway were analyzed by Western blot. Results were compared to four healthy subjects. These studies show that neither oral nor intravenous glucose improved exercise tolerance in this patient with PHK deficiency. Despite Western blots indicated affected metabolism on protein level, systemic substrate turnover studies showed that carbohydrate and fatty acid oxidations were normal.

Neurological Involvement in Glycogen Storage Disease Type IXa due to PHKA2 Mutation.

Glycogen storage diseases (GSDs) result from the deficiency of enzymes involved in glycogen synthesis and breakdown into glucose. Mutations in the gene PHKA2 encoding phosphorylase kinase regulatory subunit alpha 2 have been linked to GSD type IXa. We describe a family with two adult brothers with neonatal hepatosplenomegaly and later onset of hearing loss, cognitive impairment, and cerebellar involvement. Whole-exome sequencing was performed on both subjects and revealed a shared hemizygous missense variant (c.A1561G; p.T521A) in exon 15 of PHKA2. The phenotype broadens the clinical and magnetic resonance imaging spectrum of GSD type IXa to include later onset neurological manifestations.

Glucogenosis hepática: a propósito de un caso / Hepatic glycogenosis: a case report

RESUMEN Las glucogenosis abarcan un rango de enfermedades que se caracterizan por el almacenamiento o utilización anormal del glucógeno, siendo los órganos más afectados el músculo y/o el hígado. La hepatomegalia puede ser un signo clínico que guie al diagnóstico. Describimos a un paciente de 15 años de edad con hepatomegalia, hipertransaminasemia y retraso del crecimiento, a quien se le diagnosticó glucogenosis por biopsia hepática.

ABSTRACT The glycogen storage diseases contain a range of diseases that are characterized by the abnormal storage or utilization of glycogen, the organs most affected being muscle and / or liver. Hepatomegaly may be a clinical sign that could guide to the diagnosis. We describe a 15-year-old patient with hepatomegaly, hypertransaminasemia and growth retardation. He was diagnosed with a glycogen storage disease by liver biopsy.

Liver disease and heart failure.

INTRODUCTION: Several systemic conditions, inflammatory disease, infections and alcoholism, may affect both the heart and the liver. Common conditions, such as the non-alcoholic fatty liver disease (NAFLD), may increase the risk of cardiac dysfunction. Patients with acute decompensated HF (ADHF) may develop acute ischemic hepatitis and, chronic HF patients may develop congestive hepatopathy (CH). EVIDENCE ACQUISITION: Laboratory anomalies of hepatic function may predict the outcome of patients with advanced HF and the evaluation of both cardiac and hepatic function is very important in the management of these patients. In clinically apparent ischemic hepatitis more than 90% of patients have some right-sided HF. There are systemic disorders characterized by the accumulation of metals or by metabolism defects that may affect primarily the liver but also the heart leading to symptomatic hypertrophic cardiomyopathy (HCM). EVIDENCE SYNTHESIS: Abnormal LFTs indicate the mechanism of liver injury: liver congestion or liver ischemia. In AHF, it's important an adequate evaluation of heart and liver function in order to choose the treatment in order to ensure stable hemodynamic as well as optimal liver function. CONCLUSIONS: Measurements of LFTs should be recommended in the early phase of ADHF management. Physicians with interest in HF should be trained in the evaluation of LFTs. It's very important for cardiologists to know the systemic diseases affecting both heart and liver and the first imaging or laboratory findings useful for a diagnosis. it is very important for internists, nephrologists, cardiologists, primary physicians and any physicians with interest in treating HF to recognize such signs and symptoms belong to rare diseases and liver diseases that could be mistaken for HF.

Mitochondrial and Metabolic Myopathies.

PURPOSE OF REVIEW: This article provides an overview of mitochondrial and metabolic biology, the genetic mechanisms causing mitochondrial diseases, the clinical features of mitochondrial diseases, lipid myopathies, and glycogen storage diseases, all with a focus on those syndromes and diseases associated with myopathy. Over the past decade, advances in genetic testing have revolutionized patient evaluation. The main goal of this review is to give the clinician the basic understanding to recognize patients at risk of these diseases using the standard history and physical examination. RECENT FINDINGS: Primary mitochondrial disease is the current designation for the illnesses resulting from genetic mutations in genes whose protein products are necessary for mitochondrial structure or function. In most circumstances, more than one organ system is involved in mitochondrial disease, and the value of the classic clinical features as originally described early in the history of mitochondrial diseases has reemerged as being important to identifying patients who may have a primary mitochondrial disease. The use of the genetic laboratory has become the most powerful tool for confirming a diagnosis, and nuances of using genetic results will be discussed in this article. Treatment for mitochondrial disease is symptomatic, with less emphasis on vitamin and supplement therapy than in the past. Clinical trials using pharmacologic agents are in progress, with the field attempting to define proper goals of treatment. Several standard accepted therapies exist for many of the metabolic myopathies. SUMMARY: Mitochondrial, lipid, and glycogen diseases are not uncommon causes of multisystem organ dysfunction, with the neurologic features, especially myopathy, occurring as a predominant feature. Early recognition requires basic knowledge of the varied clinical phenotypes before moving forward with a screening evaluation and possibly a genetic evaluation. Aside from a few specific diseases for which there are recommended interventions, treatment for the majority of these disorders remains symptomatic, with clinical trials currently in progress that will hopefully result in standard treatments.

Hepatic Glycogenosis In Children: Spectrum Of Presentation And Diagnostic Modalities.

BACKGROUND: Objectives of the study were to determine the clinical spectrum of presentation and various modalities helpful in the diagnosis of liver glycogenosis short of genetic analysis. METHODS: All patients under 18 years of age presenting to Paediatric Gastroenterology unit of Children's Hospital, Lahore with suspicion of hepatic glycogen storage disease (GSD) were enrolled over a period of 18 months. Demographic profile and various factors under observation were recorded. Collected data was analysed using SPSS version 22. RESULTS: Among 89 enrolled patients F:M ratio was (1.28:1). The most common GSD was type I (71, 79.7%) followed by III (13, 14.6%), II (3, 3.3%), IV (1, 1.1%) and IX (1, 1.1%). The Abdominal distension was the most common presentation in 89.5% followed by hepatomegaly in 86.5%, diarrhoea in 41.6%, doll's like appearance in 31.5% and vomiting, acidotic breathing with convulsions in about 20% of children in GSD I. Hepatomegaly (100%), failure to thrive (85%), developmental delay (69%) and splenomegaly (92.3%) were leading presentation in GSD III. Elevated triglycerides (77.5%) followed by transaminesemia (56%), hypercholesterolemia (63%), hyperuricemia (32%) and hypoglycaemia (14%) were significant biochemical findings in GSD I. Consistently raised liver enzymes (92%) and creatinine phosphokinase (100%) in addition to hypertriglyceridemia (69%) were seen in GSD III. The presence of enlarged hepatocytes with clearing of cells favour GSD1 showed in 79% of children while fibrosis and steatosis usually seen in GSD-III (14.6%). CONCLUSIONS: Hepatic glycogen storage diseases are serious health issues and should be excluded in any patient who present with hepatomegaly, short stature and hyperlipidaemia to decrease the disease mortality and morbidity.

Hepatic glycogen storage diseases are associated to microbial dysbiosis.

INTRODUCTION: The gut microbiome has been related to several features present in Glycogen Storage Diseases (GSD) patients including obesity, inflammatory bowel disease (IBD) and liver disease. OBJECTIVES: The primary objective of this study was to investigate associations between GSD and the gut microbiota. METHODS: Twenty-four GSD patients on treatment with uncooked cornstarch (UCCS), and 16 healthy controls had their faecal microbiota evaluated through 16S rRNA gene sequencing. Patients and controls were ≥3 years of age and not on antibiotics. Faecal pH, calprotectin, mean daily nutrient intake and current medications were recorded and correlated with gut microbiome. RESULTS: Patients' group presented higher intake of UCCS, higher prevalence of IBD (n = 04/24) and obesity/overweight (n = 18/24) compared to controls (n = 0 and 06/16, respectively). Both groups differed regarding diet (in patients, the calories' source was mainly the UCSS, and the intake of fat, calcium, sodium, and vitamins was lower than in controls), use of angiotensin-converting enzyme inhibitors (patients = 11, controls = 0; p-value = 0.001) multivitamins (patients = 22, controls = 01; p-value = 0.001), and mean faecal pH (patients = 6.23; controls = 7.41; p = 0.001). The GSD microbiome was characterized by low diversity and distinct microbial structure. The operational taxonomic unit (OTU) abundance was significantly influenced by faecal pH (r = 0.77; p = 6.8e-09), total carbohydrate (r = -0.6; p = 4.8e-05) and sugar (r = 0.057; p = 0.00013) intakes. CONCLUSIONS: GSD patients presented intestinal dysbiosis, showing low faecal microbial diversity in comparison with healthy controls. Those findings might be due to the disease per se, and/or to the different diets, use of UCSS and of medicines, and obesity rate found in patients. Although the main driver of these differences is unknown, this study might help to understand how the nutritional management affects GSD patients.

Safety issues associated with dietary management in patients with hepatic glycogen storage disease.

INTRODUCTION: Hepatic glycogen storage diseases (GSDs) are a group of inherited disorders of carbohydrate metabolism for which dietary management is the cornerstone. Safety and acute complications associated with dietary management have been poorly documented. We hypothesized that safety issues and complications associated with dietary management are prevalent amongst patients with these ultra-rare disorders. METHODS: A questionnaire was developed consisting of 40 questions and was distributed via eight GSD patient organizations from multiple countries. Respondents were (caregivers of) patients with self-reported hepatic GSD. RESULTS: 249 GSD patients from 26 countries responded with a median age of 14.8 years (range: 0.5-66.1). Although management was considered safe by 71% of patients, 51% reported at least one acute complication associated with dietary management, with a total number of 425 reported complications. Most frequently reported causes were: not waking up by an alarm clock (n = 70), forgetting a meal (n = 57) and infections (n = 43). Most frequently reported complications were: hypoglycemia (n = 112), hospital admissions (n = 79) and drowsiness (n = 74). Most complications occurred before the age of 12 years (82%; 637/774 total number of reported events) and during night time (63%; 340/536). Only 61% (152/249) of the GSD patients reported using a written emergency protocol. CONCLUSIONS: Safety issues and complications associated with dietary management are prevalently reported by (caregivers of) 249 GSD patients. A discrepancy has been observed between the patient's perspective on safety of dietary management and occurrence of complications as a result of dietary management.

Sleep and quality of life of patients with glycogen storage disease on standard and modified uncooked cornstarch.

BACKGROUND: Glycemic control in hepatic glycogen storage diseases (GSDs) relies on specific nutritional recommendations, including strict avoidance of a fasting period. Uncooked cornstarch (UCCS) is an important therapeutic component. A new modified UCCS, Glycosade™, was created with the objective of prolonging euglycemia. We aimed to determine the length of euglycemia on Glycosade™ using a continuous glucose monitor (CGM) and to evaluate whether longer euglycemia and thus less nighttime interruptions would improve sleep and quality of life (QoL) after the introduction of the modified cornstarch. METHODS: We conducted a prospective cohort study to assess quality and quantity of sleep and quality of life (QoL) in patients with GSDs on standard UCCS and after the introduction of Glycosade™. Sleep and QoL evaluation was done for patients using validated questionnaires, a standardized sleep diary and actigraphy. Length of fast and glucose variability were determined with CGM. RESULTS: Nine adults with GSD Ia took part in the study. Glycosade™ introduction was done under close supervision during a hospital admission. Comparison of sleep in 9 patients showed sleep disturbances on standard UCCS that were improved with Glycosade™. QoL was normal both pre and post Glycosade™. The CGM confirmed maintenance of a longer fasting period with Glycosade™ at home. CONCLUSION: Glycosade™ represents an alternative option for GSD patients. We showed possible benefits in terms of sleep quality. We also confirmed the longer length of fast on Glycosade™. SYNOPSIS: A new modified form of uncooked starch for patients with glycogen storage disease represents an alternative option as it showed a longer length of fast and improvements in sleep quality.

Impaired glycogen breakdown and synthesis in phosphoglucomutase 1 deficiency.

OBJECTIVE: We investigated metabolism and physiological responses to exercise in an 18-year-old woman with multiple congenital abnormalities and exertional muscle fatigue, tightness, and rhabdomyolysis. METHODS: We studied biochemistry in muscle and fibroblasts, performed mutation analysis, assessed physiological responses to forearm and cycle-ergometer exercise combined with stable-isotope techniques and indirect calorimetry, and evaluated the effect of IV glucose infusion and oral sucrose ingestion on the exercise response. RESULTS: Phosphoglucomutase type 1 (PGM1) activity in muscle and fibroblasts was severely deficient and PGM1 in muscle was undetectable by Western blot. The patient was compound heterozygous for missense (R422W) and nonsense (Q530X) mutations in PGM1. Forearm exercise elicited no increase in lactate, but an exaggerated increase in ammonia, and provoked a forearm contracture. Comparable to patients with McArdle disease, the patient developed a 'second wind' with a spontaneous fall in exercise heart rate and perceived exertion. Like in McArdle disease, this was attributable to an increase in muscle oxidative capacity. Carbohydrate oxidation was blocked during exercise, and the patient had exaggerated oxidation of fat to fuel exercise. Exercise heart rate and perceived exertion were lower after IV glucose and oral sucrose. Muscle glycogen level was low normal. CONCLUSIONS: The second wind phenomenon has been considered to be pathognomonic for McArdle disease, but we demonstrate that it can also be present in PGM1 deficiency. We show that severe loss of PGM1 activity causes blocked muscle glycogenolysis that mimics McArdle disease, but may also limit glycogen synthesis, which broadens the phenotypic spectrum of this disorder.

Is Type 2 Diabetes a Glycogen Storage Disease of Pancreatic ß Cells?

Elevated plasma glucose leads to pancreatic ß cell dysfunction and death in type 2 diabetes. Glycogen accumulation, due to impaired metabolism, contributes to this "glucotoxicity" via dysregulated biochemical pathways promoting ß cell dysfunction. Here, we review emerging data, and re-examine published findings, on the role of glycogen in ß cells in normoglycemia and in diabetes.

Clinical and genetic characteristics of 17 Chinese patients with glycogen storage disease type IXa.

Glycogen storage disease (GSD) type IXa is caused by PHKA2 mutation, which accounts for about 75% of all the GSD type IX cases. Here we first summarized the clinical data and analyzed the PHKA2 gene of 17 Chinese male patients suspected of having GSD type IXa. Clinical symptoms of our patients included hepatomegaly, growth retardation, and liver dysfunction. The clinical and biochemical manifestations improved and even disappeared with age. We detected 14 mutations in 17 patients, including 8 novel mutations; exons 2 and 4 were hot spots in this research. In conclusion, glycogen storage disease type IXa is a mild disorder with a favorable prognosis, and there was no relationship between genotype and phenotype of this disease.

Skeletal muscle disorders of glycogenolysis and glycolysis.

Skeletal muscle disorders of glycogenolysis and glycolysis account for most of the conditions collectively termed glycogen storage diseases (GSDs). These disorders are rare (incidence 1 in 20,000-43,000 live births), and are caused by autosomal or X-linked recessive mutations that result in a specific enzyme deficiency, leading to the inability to utilize muscle glycogen as an energy substrate. McArdle disease (GSD V) is the most common of these disorders, and is caused by mutations in the gene encoding muscle glycogen phosphorylase. Symptoms of McArdle disease and most other related GSDs include exercise intolerance, muscle contracture, acute rhabdomyolysis, and risk of acute renal failure. Older patients may exhibit muscle wasting and weakness involving the paraspinal muscles and shoulder girdle. For patients with these conditions, engaging with exercise is likely to be beneficial. Diagnosis is frequently delayed owing to the rarity of the conditions and lack of access to appropriate investigations. A few randomized clinical trials have been conducted, some focusing on dietary modification, although the quality of the evidence is low and no specific recommendations can yet be made. The development of EUROMAC, an international registry for these disorders, should improve our knowledge of their natural histories and provide a platform for future clinical trials.

Molecular diagnosis of glycogen storage disease and disorders with overlapping clinical symptoms by massive parallel sequencing.

PURPOSE: Glycogen storage disease (GSD) is an umbrella term for a group of genetic disorders that involve the abnormal metabolism of glycogen; to date, 23 types of GSD have been identified. The nonspecific clinical presentation of GSD and the lack of specific biomarkers mean that Sanger sequencing is now widely relied on for making a diagnosis. However, this gene-by-gene sequencing technique is both laborious and costly, which is a consequence of the number of genes to be sequenced and the large size of some genes. METHODS: This work reports the use of massive parallel sequencing to diagnose patients at our laboratory in Spain using either a customized gene panel (targeted exome sequencing) or the Illumina Clinical-Exome TruSight One Gene Panel (clinical exome sequencing (CES)). Sequence variants were matched against biochemical and clinical hallmarks. RESULTS: Pathogenic mutations were detected in 23 patients. Twenty-two mutations were recognized (mostly loss-of-function mutations), including 11 that were novel in GSD-associated genes. In addition, CES detected five patients with mutations in ALDOB, LIPA, NKX2-5, CPT2, or ANO5. Although these genes are not involved in GSD, they are associated with overlapping phenotypic characteristics such as hepatic, muscular, and cardiac dysfunction. CONCLUSIONS: These results show that next-generation sequencing, in combination with the detection of biochemical and clinical hallmarks, provides an accurate, high-throughput means of making genetic diagnoses of GSD and related diseases.Genet Med 18 10, 1037-1043.